A tie includes a band that extends lengthwise from a first end to a second end. The tie also includes a housing, affixed near the second end, with a first opening to receive the first end of the band when the first end of the band is brought toward the housing in a loop. The housing includes: walls that enclose a space and have a stop toward the second end of the band; a first mass in the space; and a second mass placed in the space and between the first mass and the stop. When the first end is inserted into the housing, the first end passes under the first mass and the second mass and exerts a pull on the first mass toward the second mass. When the first mass is pulled toward the second mass, the second mass acts as a spring between the first mass and the stop and prevents the first mass from hitting the stop.
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9. A tie comprising:
a band having a first end and a second end;
a housing, affixed to the band near the second end, with a first opening to receive the first end of the band, configured to lock the first end of the band in place when the housing receives the first end via the first opening;
wherein the band includes wave springs attached in series;
wherein each of the wave springs includes:
an upper arc that is convex relative to one surface of the band; and
a lower arc that is lengthwise parallel to the upper arc and convex relative to another surface of the band;
wherein when the band is wrapped about one or more items and tightened, stretching forces are applied on the wave springs and the wave springs apply restorative forces on the band, resulting in a tension, throughout the band, that prevents the band from providing slack to the first end,
wherein the housing comprises:
a first mass and a second mass in a space enclosed by the housing,
wherein, after the first end is inserted into the housing and when the first end is being pulled out of the housing, the first mass squeezes the first end against a bottom of the housing and locks the first end in the housing, and
wherein the second mass prevents the first mass from moving about in the space and prevents the first mass from allowing the first end to slip.
1. A tie comprising:
a band including a bottom surface and a top surface, comprising:
a front section that extends lengthwise from one end of the band,
a spring section that extends lengthwise from the front section, and
an end section that extends lengthwise from the spring section; and
a housing, affixed near the front section, with a first opening to receive the end section of the band when the end section of the band is brought toward the housing in a loop, wherein the housing is configured to lock the end section of the band in place when the housing receives the end section via the first opening;
wherein the spring section includes wave springs attached in series;
wherein one end of a first of the wave springs is attached to the front section, and the other end of the first of the wave springs is attached to one end of a second of the wave springs;
wherein each of the wave springs comprises:
an upper arc that is convex relative to the top surface of the band;
a lower arc that is lengthwise parallel to the upper arc and that is convex relative to the bottom surface of the band; and
an end piece to which the upper arc and the lower arc are attached; and
wherein when the band is wrapped about one or more items, the end section is inserted into the housing, and the band is tightened about the items, the front section and the end section apply stretching forces on the wave springs of the spring section and the wave springs apply restorative forces on the band, resulting in a tension throughout the band,
wherein the housing comprises:
walls that enclose a space and have a stop toward the end section of the band;
a first mass in the space; and
a second mass placed in the space and between the first mass and the stop;
wherein when the end section is inserted into the housing, the end section passes under the first mass and the second mass and exerts a pull on the first mass toward the second mass,
wherein when the first mass is pulled toward the second mass, the second mass acts as a spring between the first mass and the stop and prevents the first mass from hitting the stop, and
wherein, after the end section is inserted into the housing and when the end section is being pulled out of the housing, due to a force exerted by the second mass to the first mass and the walls, the first mass squeezes the end section against a bottom of the housing and locks the end section in the housing.
3. The tie of
5. The tie of
another lower arc that is lengthwise parallel to the upper arc and that is convex relative to the bottom surface of the band.
7. The tie of
11. The tie of
13. The tie of
another lower arc that is lengthwise parallel to the upper arc and that is convex relative to the other surface of the band.
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This application claims priority under 35 U.S.C. §119 based on U.S. Provisional Patent Application No. 62/067,856 filed Oct. 25, 2014, the disclosure of which is incorporated by reference herein in its entirety.
A cable tie is used for fastening, binding, bundling, and/or organizing cables/wires, pipes, pieces of wood, and/or any other items/load that can be tied with rope, rape, etc. Different types of cable ties are made for use in different environments and applications. For example, some cable ties are made for outdoor use. Some cable ties are made for a specific industry, such as the food industry. Some are made for heavy-duty use (e.g., cable ties made of metal), for bundling large cables.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate one or more embodiments described herein and, together with the description, explain the embodiments. In the drawings:
The following detailed description refers to the accompanying drawings. The same reference numbers in different drawings may identify the same or similar elements.
As used herein, the term “cable tie” may refer to a tie for binding different types of items, such as wires, cables, pipes, etc.
As described herein, an anti-slip cable tie may provide for a small/minimum slack in binding, fastening or bundling cables. To tie/bundle cables using the anti-slip cable tie, one end of a band, of the cable tie, that encircles the cables is inserted into the housing of a locking body of the cable tie. When the end of the band is inserted within the housing of the locking body, the band pushes a ball bearing within the housing toward an inner wall of the housing. Another ball within the housing, however, prevents the ball bearing from moving backwards beyond a point and bumping into the inner wall. When the band is pulled/tugged in the forward direction away from the inner wall, the ball bearing, being close to a front of the wall, prevents the end of the band from slipping and locks the band in place. Because the other ball prevents the ball bearing from moving about in the housing, the ball bearing continues to lock the band in place.
When band 104 is wrapped about cables and an end of band 104 (e.g., section 116-3) is inserted within locking body 102, locking body 102 prevents the end from slipping back out of locking body 102 and the band from unwrapping about the cables.
Locking body 102 includes a side wall 106-1, a top wall 106-2, a side wall 106-3, bottom walls 106-4 and 106-5 (shown in
Housing 108 includes a side portion 110-1 (also referred to as a “stop 110-1”), a top portion 110-2, and a side portion 110-3 (collectively referred to as “portions 110”). As further described below, portions 110 are configured/shaped to enclose and interact with elements within housing 108, to prevent a portion of band 104 (which was inserted through opening 114-1 and 114-2) from sliding out from housing 108 when anti-slip cable tie 100 is in the closed configuration. In
Band 104 includes an entrance section 116-1, a middle section 116-2, and an end section 116-3. Band 104 also includes edges, two of which are illustrated as a side edge 120-1 and front edge 120-3. In one embodiment, side edge 120-1 and front edge 120-3 form an acute angle, such that, along the side edge 120-1 and parallel to the x-axis, the end of band 104 tapers to a tip 122 that can be more easily inserted into a gap/opening 114-2 (see
As shown in
In this configuration, side walls 106-1 and 106-3 of locking body 102, clip 124, and tab 128 hold/affix a portion of locking body 102 to an interior portion of band 104, with the bottom surface 118-2 of band 104 being flush with an interior surface (the surface within locking body 102) of bottom walls 106-4 and 106-5 and the top surface of flap 126 being flush with the exterior surface (the surface in the −z direction) of bottom walls 106-4 and 106-5. Side walls 106-1 and 106-3 prevent the interior portion of band 104 from moving laterally in the negative/positive y-direction with respect to locking body 102. Clip 124, which is integral to band 124, prevents locking body 102 from sliding in the negative/positive x-direction relative to the interior portion of band 104. Tab 128, having been pushed into the hole in bottom walls 106-4 and 106-5, catches an edge of the hole when an external force is applied to locking body 102 relative to the interior portion of band 104 in the positive x-direction. Tab 128 and the hole prevents locking body 102 from sliding in the x-direction relative to the interior portion of band 104.
As briefly discussed above, in a different embodiment without sphere 306 in space 302, when end section 116-3 is inserted into housing 108, end section 116-3 may cause ball bearing 304 to move all the way (or significant portion of the way) to stop 110-1 of housing 108. With ball bearing 304 in such a position, if band 104 were pulled back in the direction of arrow 419 (e.g., due to the weight of cables that are bound by cable tie 100), as end section 116-3 moves in the same direction relative to housing 108, ball bearing 304 would also move from the stop 110-1 of housing 108 toward the interior surface of portion 110-3 of housing 108, until ball bearing 304 locks end section 116-3, and, therefore, band 104. The distance covered by ball bearing 304 until ball bearing 304 locks band 104 is approximately the amount of slippage of band 104 allowed by cable tie 100. The slippage may result in an undesirable amount of slack in band 104 when cable tie 100 is in the closed configuration, with band 104 wrapped about cables/wires.
In contrast, with sphere 306 in place as illustrated in
In a typical implementation, cube 606 may be made of resilient material, such as stainless steel or stainless steel wire mesh. Depending on the implementation, cube 606 may be replaced by a stainless steel mesh of another shape, such as a round ball, cylinder, rectangular box/prism, etc. In contrast to portions 110 in
Portions 612 may be dimensioned to properly accommodate ball bearing 608 and sphere 610. In some implementations, both ball bearing 608 and sphere 610 may be composed of the same or similar materials (e.g., stainless steel).
In some implementations, interior portion 308 may include a “dimple” or a hole. In other implementations, interior portion 308 excludes (i.e., is without) a dimple or a hole. If a hole or a dimple exists on interior portion 308, when section 116-3 is fully inserted into housing 108, bearing/sphere (e.g., any one of bearing 304, sphere 306, cylinder 502, cube 606, bearing 608, sphere 610, or sphere 614) may drive the area (of section 116-3) on which the bearing sits into the hole (on interior portion 308) underneath section 116-3. In this way, the dimple or hole on interior portion 308 may further stabilize the bearing/sphere. when section 116-3 is locked by the bearing/sphere.
Locking body 702 includes similar components as locking body 102 and is made of the same material as locking body 102. In addition, locking body 702 may operate similarly as locking body 102.
Band 704 includes similar components and is made of the same material as band 104. Band 704 also operates similarly to band 104. In contrast to band 102, however, band 704 includes front section 716-1, spring section 716-2, and end section 716-3.
As further shown, spring section 716-2 includes five wave springs, 722, 726, 730, 734, and 738. Each of wave springs 722, 726, 730, and 734 includes downward arcs, an upward arc, and an end piece. For example, wave spring 722 includes downward arcs 722-1 and 722-3, upward arc 722-2, and end piece 724. As shown, each of wave springs 726, 730, and 734 include similar components as wave spring 722. Wave spring 738 is slightly different from other wave springs 722, 726, 730, and 734 in that wave spring 738 does not include an end piece.
A downward arc may include a strip that is curved convex relative to the bottom surface of band 704 (the downward arc is also curved concave relative to the top surface of band 704). Conversely, an upward arc may include a strip that is curved convex relative to the top surface of band 704 (the upward arc is also curved concave relative to the bottom surface of band 704). For wave spring 722, one end of downward arc 722-1 is attached to a piece that precedes wave spring 722 (i.e., front section 716 in this case) and the other end of downward arc 722-1 is attached to end piece 724. Similarly, one end of downward arc 722-3 is attached to a piece that precedes wave spring 722 (i.e., front section 716) and the other end of downward arc 722-3 is attached to end piece 724. Upward arc 722-2 is similarly configured. The arcs of other wave springs 726, 730, and 734 are arranged similarly as those of wave spring 722. For wave spring 738, one ends of downward arcs 738-1 and 738-3 and upward arc 738-2 are attached to end section 716-3 (since there is no end piece for wave spring 738).
For each of the wave springs 722, 726, 730, and 734, its end piece interconnects its upward and downward arcs. (e.g., arcs 722 are connected to one other via end piece 724). Hence, each end piece allows the corresponding wave spring to function as a single unit and provides necessary rigidity to the wave spring. Without the end piece, for example, downward arc 722-1 of wave spring 722 would be directly attached to arc 726-1 of the next wave spring 726, and thus form a continuous series of arcs. The series of arcs 722-1 and 726-1 would be free to move relative to another series of upward arcs (i.e., 722-2 and 726-2) parallel to downward arcs 722-1 and 726-1.
As illustrated in
As shown, as the result of tightening cable tie 700, pulling forces are applied to the ends of arcs 722-1 through 722-3 in the directions of arrows 750 and 754, by front section 716-1 and end piece 724. The forces widen (or spread apart) arcs 722-1 through 722-3 in the same directions as the arrows. As the arcs widen, the arcs exert restorative forces (spring's force) in the directions opposite to those the arrows, to front section 716-1 and end piece 724. The restorative forces from each of the wave springs 722, 726, 730, 734, and 738 are transmitted throughout band 704, keeping tie 700 tight around the load and in equilibrium against the pulling forces. The constant tension in cable tie 700 may keep end section 716-3 in locking body 702 from sliding further into body 702 (e.g., due to vibration or other disturbances) and may prevent locking mechanisms within locking body 702 (e.g., square/cube 606, ball bearing 608, sphere 610, etc.) from moving and providing slack to cable tie 700. That is, the tension allows cable tie 700 to absorb any vibrations that may cause, without the wave springs, over time, locking body 702 to disengage band 704 or tie 700 from becoming loose.
When tie 700 is wrapped around a load, a portion(s) on the underside of arc 702-1 (as shown by arrow 752) may contact the load. The portion in contact with the load may experience a force applied by the load, as the result of tie 700 being wrapped about the load. For example, assume that the load contacts the portion of arc 722-1 at the point of arrow 752. The portion would experience a force in the direction of arrow 752. The force would result in further widening of lower arc 722-1. The restorative forces due to upper arc 722-2 may aid in counteracting the widening. That is, upper arc 722-2 provides reinforcement to lower arcs 722-1 and 722-3.
In
Although
The foregoing description of implementations provides illustration, but is not intended to be exhaustive or to limit the implementations to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of the teachings. For example, in some implementations, housing 108 may be shaped differently than that illustrated in
Although different implementations have been described above, it is expressly understood that it will be apparent to persons skilled in the relevant art that the implementations may be modified without departing from the spirit of the invention. Various changes of form, design, or arrangement may be made to the invention without departing from the spirit and scope of the invention. Therefore, the above mentioned description is to be considered exemplary, rather than limiting, and the true scope of the invention is that defined in the following claims.
It should be emphasized that the term “comprises/comprising” when used in this specification is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components, or groups thereof.
No element, act, or instruction used in the present application should be construed as critical or essential to the implementations described herein unless explicitly described as such. Also, as used herein, the article “a” is intended to include one or more items. Further, the phrase “based on” is intended to mean “based, at least in part, on” unless explicitly stated otherwise.
Cole, Andrew C., Rufty, Ryan M.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Oct 22 2015 | Thomas & Betts International LLC | (assignment on the face of the patent) | / | |||
Jan 14 2016 | COLE, ANDREW C | THOMAS & BETTS INTERNATIONAL, LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 037677 | /0136 | |
Apr 19 2017 | RUFTY, RYAN M | Thomas & Betts International LLC | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 042064 | /0623 |
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